Apparatus and methods for producing a glass ribbon

ABSTRACT

Apparatus for producing glass ribbon includes a control device configured at least periodic thermal stress compensation of the glass ribbon by independently adjusting operation of a plurality of temperature adjustment elements based on stress characteristic information at least periodically obtained from a stress sensor apparatus. In further examples, methods of producing glass include at least periodically sensing a stress characteristic of a glass ribbon and at least periodically changing a transverse temperature profile of the glass ribbon based stress characteristic information. In further examples, methods include the step of changing a transverse temperature profile of the glass ribbon only if a measured parameter is within an operating range associated with the parameter.

FIELD

The present invention relates generally to apparatus and methods forproducing glass ribbon and, more particularly, to apparatus and methodsfor producing a glass ribbon with a plurality of temperature adjustmentelements.

BACKGROUND

It is known to draw a glass ribbon with a draw device. The glass ribbonmay be subsequently divided to produce a plurality of glass sheets thatmay be employed in a wide range of applications. The glass ribbon isknown to be drawn in a viscous state for eventual cooling into anelastic state where final features, such as stress characteristics, arepermanently set into the glass sheet.

SUMMARY

The following presents a simplified summary of the disclosure in orderto provide a basic understanding of some example aspects described inthe detailed description.

In one example aspect, an apparatus for producing glass ribbon comprisesa drawing device configured to draw molten glass into a glass ribbon ina draw direction along a draw plane of the apparatus. The apparatusfurther includes a temperature adjustment apparatus including aplurality of temperature adjustment elements positioned at respectivelateral locations along at least one temperature adjustment axisextending transverse to the draw direction. The temperature adjustmentelements are configured to adjust a transverse temperature profile ofthe glass ribbon along a width of the glass ribbon. The apparatusfurther includes a stress sensor apparatus configured to measure astress characteristic of the glass ribbon at respective locations alonga width of the glass ribbon. The apparatus further includes a controldevice configured for at least periodic thermal stress compensation ofthe glass ribbon by independently adjusting operation of the temperatureadjustment elements based on stress characteristic information at leastperiodically obtained from the stress sensor apparatus.

In another example aspect, methods of producing a glass ribbon includethe steps of drawing molten glass in a draw direction into a viscouszone to form a glass ribbon including opposed edges extending in thedraw direction. The opposed edges are spaced apart along a width of theglass ribbon that is transverse to the draw direction. The methodfurther includes the step of drawing the molten glass from the viscouszone into a setting zone downstream from the viscous zone. The glassribbon is set from a viscous state to an elastic state. The methodfurther includes the step of drawing the glass ribbon into an elasticzone downstream from the setting zone. The method still further includesthe step of at least periodically sensing a stress characteristic of theglass ribbon at respective lateral locations along the width of theglass ribbon. The method further includes the step of at leastperiodically changing a transverse temperature profile of the glassribbon by independently adjusting operation of a plurality oftemperature adjustment elements positioned along the width of the glassribbon in at least one of the viscous zone, the setting zone and theelastic zone. The temperature adjustment elements are independentlyadjusted based on stress characteristic information obtained during thestep of sensing the stress characteristic.

In still another example aspect, a method of producing a glass ribbonincludes the step of drawing molten glass in a draw direction into aviscous zone to form a glass ribbon including opposed edges extending inthe draw direction. The opposed edges are spaced apart along a width ofthe glass ribbon that is transverse to the draw direction. The methodfurther includes the step of drawing the molten glass from the viscouszone into a setting zone downstream from the viscous zone, wherein theglass ribbon is set from a viscous state to an elastic state. The methodstill further includes the step of drawing the glass ribbon into anelastic zone downstream from the setting zone. The method also includesthe step of measuring a parameter associated with mechanically inducedstress in the glass ribbon. The method further includes the step ofchanging a transverse temperature profile of the glass ribbon only ifthe measured parameter is within an operating range associated with theparameter. The temperature profile can be changed by independentlyadjusting operation of a plurality of temperature adjustment elementspositioned along the width of the glass ribbon in at least one of theviscous zone, the setting zone and the elastic zone. The temperatureadjustment elements are independently adjusted based on stresscharacteristic information obtained by sensing the glass ribbon atrespective lateral locations along the width of the glass ribbon.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features, aspects and advantages of the presentdisclosure are better understood when the following detailed descriptionis read with reference to the accompanying drawings, in which:

FIG. 1 is a schematic illustration of an example apparatus for producingglass ribbon in accordance is aspects of the disclosure;

FIG. 2 illustrates a sectional view of a forming vessel of the apparatusalong line 2-2 of FIG. 1;

FIG. 3 schematically illustrates a glass ribbon being drawn off theforming vessel of FIG. 1; and

FIG. 4 illustrates example process steps for producing a glass ribbon inaccordance with aspects of the disclosure.

DETAILED DESCRIPTION

Methods will now be described more fully hereinafter with reference tothe accompanying drawings in which example embodiments of the disclosureare shown. Whenever possible, the same reference numerals are usedthroughout the drawings to refer to the same or like parts. However,this disclosure may be embodied in many different forms and should notbe construed as limited to the embodiments set forth herein.

Apparatus can be provided for producing a glass ribbon for subsequentprocessing into glass sheets. FIG. 1 schematically illustrates a fusiondraw apparatus 101 although up draw, slot draw or other glass formingtechniques may be used with aspects of the disclosure in furtherexamples. With such fusion draw process techniques, the presentdisclosure provides for at least periodic, such as continuous, thermalstress compensation of the glass ribbon by independently adjustingoperation of a plurality of temperature adjustment elements. Forinstance, adjustment of power to the plurality of temperature adjustmentelements can help control stress within the glass ribbon before thestress profile is frozen into the ribbon as the glass ribbon enters theelastic zone as discussed more fully below. As such, by processingtechniques of the present disclosure, fine tune adjustment of thetransverse stress profile can be achieved to avoid stress concentrationsand/or resulting optical discontinuities.

As illustrated, the fusion draw apparatus 101 can include a meltingvessel 105 configured to receive batch material 107 from a storage bin109. The batch material 107 can be introduced by a batch delivery device111 powered by a motor 113. An optional controller 115 can be configuredto activate the motor 113 to introduce a desired amount of batchmaterial 107 into the melting vessel 105, as indicated by arrow 117. Ametal probe 119 can be used to measure a molten glass 121 level within astandpipe 123 and communicate the measured information to the controller115 by way of a communication line 125.

The fusion draw apparatus 101 can also include a fining vessel 127, suchas a fining tube, located downstream from the melting vessel 105 andcoupled to the melting vessel 105 by way of a first connecting tube 129.A mixing vessel 131, such as a stir chamber, can also be locateddownstream from the fining vessel 127 and a delivery vessel 133 may belocated downstream from the mixing vessel 131. As shown, a secondconnecting tube 135 can couple the fining vessel 127 to the mixingvessel 131 and a third connecting tube 137 can couple the mixing vessel131 to the delivery vessel 133. As further illustrated, a downcomer 139can be positioned to deliver molten glass 121 from the delivery vessel133 to a drawing apparatus. Fusion draw apparatus 101, including theillustrated fusion draw machine 140, is configured to draw molten glassinto a glass ribbon as discussed more fully below. In one example, thefusion draw machine 140 can include a forming vessel 143 provided withan inlet 141 to receive molten glass from the downcomer 139.

As shown, the melting vessel 105, fining vessel 127, the mixing vessel131, delivery vessel 133, and forming vessel 143 are examples of moltenglass stations that may be located in series along the fusion drawapparatus 101.

The melting vessel 105 is typically made from a refractory material,such as refractory (e.g. ceramic) brick. The fusion draw apparatus 101may further include components that are typically made from platinum orplatinum-containing metals such as platinum-rhodium, platinum-iridiumand combinations thereof, but which may also comprise such refractorymetals such as molybdenum, palladium, rhenium, tantalum, titanium,tungsten, ruthenium, osmium, zirconium, and alloys thereof and/orzirconium dioxide. The platinum-containing components can include one ormore of the first connecting tube 129, the fining vessel 127 (e.g.,finer tube), the second connecting tube 135, the standpipe 123, themixing vessel 131 (e.g., a stir chamber), the third connecting tube 137,the delivery vessel 133 (e.g., a bowl), the downcomer 139 and the inlet141. The forming vessel 143 is also made from a refractory material andis designed to form the glass ribbon 103.

FIG. 2 is a cross-sectional perspective view of the fusion drawapparatus 101 along line 2-2 of FIG. 1. As shown, the forming vessel 143includes a forming wedge 201 comprising a pair of downwardly inclinedforming surface portions 203, 205 extending between opposed ends of theforming wedge 201. The pair of downwardly inclined forming surfaceportions 203, 205 converge along a draw direction 207 to form a root209. A draw plane 211 extends through the root 209 wherein the glassribbon 103 may be drawn in the draw direction 207 along the draw plane211. As shown, the draw plane 211 can bisect the root 209 although thedraw plane 211 may extend at other orientations with respect to the root209.

The fusion draw apparatus 101 for fusion drawing a glass ribbon can alsoinclude at least one edge roller assembly including a pair of edgerollers configured to engage a corresponding edge 103 a, 103 b of theglass ribbon 103 as the ribbon is drawn off the root 209 of the formingwedge 201. The pair of edge rollers facilitates proper finishing of theedges of the glass ribbon. Edge roller finishing provides desired edgecharacteristics and proper fusion of the edge portions of the moltenglass being pulled off opposed surfaces of an edge director 212associated with the pair of downwardly inclined forming surface portions203, 205. As shown in FIG. 2, a first edge roller assembly 213 a isassociated with the first edge 103 a. FIG. 3 shows a second edge rollerassembly 213 b associated with the second edge 103 b of the glass ribbon103. Each edge roller assembly 213 a, 213 b can be substantiallyidentical to one another although the pairs of edge rollers may havedifferent characteristics in further examples. As shown in FIG. 1, oncethe edges 103 a, 103 b of the glass ribbon 103 are formed, a width “W”of the glass ribbon 103 is defined between the edges 103 a, 103 b in adirection substantially perpendicular to the draw direction 207.

As shown in FIG. 3, the fusion draw apparatus 101 can further include afirst and second pull roll assembly 301 a, 301 b for each respectiveedge 103 a, 103 b to facilitate pulling of the glass ribbon 103 in thedraw direction 207 of the draw plane 211.

The fusion draw apparatus 101 can further include a cutting device 303that allows the glass ribbon 103 to be cut into distinct glass sheets305. The glass sheets 305 may be subdivided into individual glass sheetsfor incorporating in the various display devices, such as a liquidcrystal display (LCD). Cutting devices may include laser devices,mechanical scoring devices, traveling anvil machines and/or otherdevices configured to cut the glass ribbon 103 into the distinct glasssheets 305.

Referring to FIG. 2, in one example, the molten glass 121 can flow intoa trough 215 of the forming vessel 143. The molten glass 121 can thensimultaneously flow over corresponding weirs 217 a, 217 b and downwardover the outer surfaces 219 a, 219 b of the corresponding weirs 217 a,217 b. Respective streams of molten glass then flow along the downwardlyinclined forming surface portions 203, 205 to the root 209 of theforming vessel 143, where the flows converge and fuse into the glassribbon 103. The glass ribbon 103 is then drawn off the root 209 in thedraw plane 211 along draw direction 207.

Turning to FIG. 3, the glass ribbon 103 is drawn from the root 209 inthe draw direction 207 of the draw plane 211 from a viscous zone 307 toa setting zone 309. In the setting zone 309, the glass ribbon 103 is setfrom a viscous state to an elastic state with the desiredcross-sectional profile. The glass ribbon is then drawn from the settingzone 309 to an elastic zone 311. In the elastic zone 311, the profile ofthe glass ribbon from the viscous zone 307 is frozen as a characteristicof the glass ribbon. While the set ribbon may be flexed away from thisconfiguration, internal stresses can cause the glass ribbon to bias backto the original set profile.

As shown in FIGS. 2-3, any of the apparatus for producing glass ribbon103 can include a temperature adjustment apparatus 221. For instance, asshown in FIG. 2, the temperature adjustment apparatus 221 can include aplurality of temperature adjustment elements 223 that can be positionedat respective lateral locations 225 along at least one temperatureadjustment axis extending transverse, such as perpendicular, to the drawdirection 207.

As shown, the temperature adjustment apparatus 221 can provide the atleast one axis as a first temperature adjustment axis 227 a and a secondtemperature adjustment axis 227 b, although a single or three or moretemperature adjustment axes may be provided in further examples. Asshown, the first and second temperature adjustment axis 227 a, 227 b caneach comprise a substantially straight axis although curved or otheraxis shapes may be provided in further examples. Still further, thefirst and second axis 227 a, 227 b are substantially parallel to oneanother although the axes may be angled with respect to one another infurther examples.

The temperature adjustment axis may be located in a wide variety ofelevations with respect to the glass ribbon. For example, as shown inFIGS. 2 and 3, the first and second temperature adjustment axis 227 a,227 b are located within the setting zone 309. In addition, oralternatively, each or at least one temperature adjustment axis may belocated within the viscous zone 307 and/or within the elastic zone 311in further examples.

As mentioned previously, as shown in FIG. 2, the plurality oftemperature adjustment elements 223 can be located at respective laterallocations 225, wherein the temperature adjustment elements areconfigured to adjust a transverse temperature profile of the glassribbon 103 along the width “W” of the glass ribbon 103. As shown in FIG.2, each of the plurality of temperature adjustment elements 223 on eachtemperature adjustment axis may be spaced from one another in seriesalong the respective temperature adjustment axis. For example, as shownin FIG. 2, one of the temperature adjustment elements 223 may be locatedat a lateral location 225 that is a distance “L₁” from the edge 103 a ofthe glass ribbon 103 while the adjacent temperature adjustment element223 can be located a distance “L₂” from the edge 103 a that is greaterthan the distance “L₁”. In some examples the temperature adjustmentelements 223 can be spaced equally from one another along the width “W”of the glass ribbon although the temperature adjustment elements may belocated at different distances relative to the edges 103 a, 103 b of theglass ribbon. For example, the temperature adjustment elements 223 maybe located closer together near the edges 103 a, 103 b when compared toa central region of the glass ribbon 103 to allow greater transfer ofheat at the edges than the central portion of the glass ribbon.

As shown, the temperature adjustment elements 223 can be spaced apartfrom one another along a single row although a matrix of temperatureadjustment elements may be provided in further examples. As shown, thetemperature adjustment elements 223 can also be substantially identicalto one another although different sized or types of elements may be usedin further examples. For instance, in one example, the temperatureadjustment element size and/or type may be designed to allow greaterheat transfer to the edges when compared to the central portion of theglass ribbon. In one example, the temperature adjustment elements 223can comprise heating coils wherein heat is generated by electricalresistance from electrical current passing through the heating coils.

As further illustrated in FIG. 3, the apparatus 101 can further includea stress sensor apparatus 313 configured to measure a stresscharacteristic of the glass ribbon 103 at respective locations 315 alongthe width “W” of the glass ribbon 103. The stress sensor apparatus, forexample, can include at least one sensor element. For instance, a singlesensor element may be provided that travels along the width of the glassribbon 103 to measure a stress characteristic of the glass ribbon.

Alternatively, as shown, in further examples the stress sensor apparatus313 can include a plurality of sensor elements 317 configured to measurea stress characteristic of the glass ribbon 103 at the respectivelocations 315 along the width “W” of the glass ribbon 103. In oneexample, the sensor elements 317 can be positioned at the respectivelocations 315 in series along at least one stress sensing axis. Forinstance, the plurality of sensor elements 317 can be positioned atrespective locations 315 along a first stress sensing axis 319 andconfigured to extend along the width “W” of the glass ribbon 103 withinthe elastic zone 311. In addition or alternatively, the sensor elements317 can be aligned along a second stress sensing axis 321 within asevered zone 312 while extending across a width “W” of the glass ribbonthat forms distinct glass sheets 305 that have been severed from theupstream portion of the glass ribbon 103.

A single first stress sensing axis 319 can be provided within theelastic zone 311 and/or a single second stress sensing axis 321 can beprovided within the severed zone 312. In further examples, a pluralityof sensor axes may be provided within the elastic zone 311 and/or withinthe severed zone 312. In such examples, the plurality of respectivesensor axes may be substantially parallel to one another although theaxes may be angled from one another in further examples. Still further,as shown, each stress sensing axis 319, 321 may be substantiallystraight although the sensor axes may be curved or have differentprofiles in further examples. As shown, both of the sensing axis 319,321 extend substantially perpendicular, to the draw direction 207.Although not shown, one or both of the sensing axes may be positioned atother orientations transverse to the draw direction 207.

In the example shown in FIG. 3, an outermost sensor element 317 may belocated at a lateral location 315 that is a distance “L₁” from the edge103 a of the glass ribbon 103 while the adjacent sensor element 317 canbe located a distance “L₂” from the edge 103 a that is greater than thedistance “L₁”. In some examples the sensor elements 317 can be spacedequally from one another along the width “W” of the glass ribbonalthough sensor elements may be located at different distances relativeto the edges 103 a, 103 b of the glass ribbon. For example, the sensorelements 317 may be located closer together near the edges 103 a, 103 bwhen compared to a central region of the glass ribbon 103 to allowsensing that matches the location of the corresponding laterally spacedtemperature adjustment elements 223. As such, the plurality of sensorelements 317 may be configured to measure a stress characteristic of theglass ribbon 103 at respective locations 315 along the stress sensingaxis 319, 321 that corresponds to the lateral location 225 of acorresponding temperature adjustment element 223 of the plurality oftemperature adjustment elements 223.

The sensor elements 317 can comprise various configurations adapted tosense stress at a particular location of the glass ribbon 103 beforeand/or after severing the glass ribbon. In one example, the sensorelement 317 can comprise a device configured to use polarized light todetermine stress at a particular location. With such examples, thepolarized light can be used to determine the stress characteristicwithout destroying the glass ribbon. As such, the stress sensorapparatus 313 can facilitate periodic, such as continuous, monitoring ofa stress condition at a particular lateral location of the glass ribbonbefore and/or after severing the glass ribbon.

As also illustrated in FIG. 3, the apparatus 101 can further include acontrol device 323 configured for at least periodic, such as continuous,thermal stress compensation of the glass ribbon 103 by independentlyadjusting operation of the temperature adjustment elements 223 based onstress characteristic information at least periodically, such ascontinuously, obtained from the stress sensor apparatus 313. In oneexample, the control device 323 can include a controller 325 incommunication with the plurality of temperature adjustment elements 223and the sensor elements 317. For example, as shown the plurality ofsensor elements 317 associated with the stress sensing axes 319, 321 canbe placed in communication with the controller 325 by way ofcommunication lines 327, 329. Likewise, the plurality of temperatureadjustment elements 223 associated with the temperature adjustment axes227 a, 227 b can be placed in communication with the controller 325 byway of respective communication lines 331, 333.

In one example, the control device 323 can comprise a database listing arelationship between power adjustments and corresponding impact on astress characteristic of a glass sheet. For example, the database can bebased on a fixed listing of previous power adjustments and thecorresponding observed impact on stress characteristic. In one example,the database is fixed, wherein the same database may be used for futurepower adjustments to compensate for stress within the glass ribbon. Infurther examples, the database may be dynamic, wherein the database maybe updated over time to include new data. For example, the database maybe configured to adapt the relationship between the power adjustmentsand the corresponding impact on the stress characteristic of the glasssheet based on the stress characteristic information obtained from thestress sensor apparatus after adjusting the operation of the temperatureadjustment elements.

In further examples, the control device 323 can logically carry outpower adjustments to minimize a stress characteristic of the glassribbon 103. For example, a mathematical model of the relationshipsbetween temperature adjustment element power moves and resulting stresswithin the glass ribbon can be used to carry out the power adjustments.An example of a nonlinear dynamic expression relating winding power tostress can be represented by equations (1) below:

{dot over (S)}=f(s)+g(s)p

S _(o) =S  (1)

where s is a vector of stress points, p is a vector of winding powers,the functions f and g are appropriately sized vector fields, and s_(o)is the output stress vector.

An example of a nonlinear dynamic expression relating winding power tostress can be represented by the following equation (2) below:

s=Kp  (2)

where K is an appropriately sized matrix mapping power to stress.Equation (2) may be derived from equation (1) above during staticconditions.

In still further examples, the control device 323 can optionallyincorporate a fuzzy logic controller although other control devices maybe used in further examples.

In further examples, the apparatus 101 can include a parameter sensor335 configured to sense a condition of a parameter associated with theapparatus 101. For example, the parameter sensor 335 sense a conditionthat may indicate that mechanically induced stress is dominant in theglass ribbon. In such situations, it may be beneficial to avoidattempting to reduce thermal-related stress until mechanical-relatedstresses are mitigated. In one example, the parameter sensor 335 can bea motion sensor to determine a motion of the glass ribbon. In anotherexample, the parameter sensor 335 may comprise a temperature sensor todetermine temperature differentials across the width of the glassribbon. In still further examples, the parameter sensor 335 may comprisea proximity sensor configured to measure a shape of the glass ribbon. Instill further examples, the parameter sensor 335 can comprise a laser orother device configured to determine a physical condition of the glassribbon. With any such examples including a parameter sensor, a conditionof the parameter associated with the apparatus 101 may be sensed afterwhich the control device 323 is configured to prevent thermal stresscompensation if a predetermined condition is sensed by the parametersensor 335.

Methods of producing the glass ribbon 103 will now be described withrespect to FIGS. 1-4. As described above, the molten glass 121 can bedrawn in the draw direction 207 to form the glass ribbon 103 includingopposed edges 103 a, 103 b extending in the draw direction 207. Asmentioned previously and as shown in FIG. 1, the opposed edges 103 a,103 b are spaced apart along the width “W” of the glass ribbon 103 thatis transverse to the draw direction 207.

The method further includes the step of drawing the molten glass 121from the viscous zone 307 into a setting zone 309 downstream from theviscous zone 307, wherein the glass ribbon 103 is set from a viscousstate to an elastic state. The method still further includes the step ofdrawing the glass ribbon 103 into the elastic zone 311 downstream fromthe setting zone 309.

Referring to FIG. 4, in one example, the method can then continue withthe step 401 of sensing a stress characteristic of the glass ribbon 103at respective lateral locations along the width “W” of the glass ribbon103. For example, as shown in FIG. 3, the plurality of sensor elements317 can at least periodically sense a stress characteristic associatedwith the respective lateral location (e.g., L₁, L₂, etc.) of the glassribbon 103. In further examples, the sensors may continuously measurethe stress characteristic associated with the respective laterallocation of the glass ribbon.

As shown in FIG. 3, the sensors may be aligned along the first stresssensing axis 319 to at least periodically, such as continuously, measurethe stress characteristic associated with the respective laterallocation of the glass ribbon within the elastic zone 311 prior tosevering the glass ribbon into distinct glass sheets 305.

In addition, or alternatively, as further shown in FIG. 3, the sensorsmay be aligned along the second stress sensing axis 321 to at leastperiodically, such as continuously, measure the stress characteristicassociated with the respective lateral location of the glass ribbonafter the glass sheet 305 is severed from the glass ribbon. In such anexample, the sensors may measure the stress characteristic along thelength of every glass sheet 305. For example, the sensors may carry outa signal measurement of the stress characteristic along the secondstress sensing axis at a particular location along the length of everyglass sheet 305. In such an example, the sensors periodically measureeach glass sheet a single time. In further examples, the sensors maycarry out periodic measurements of the stress characteristic along thesecond stress sensing axis 321 at multiple locations along the length ofevery glass sheet 305. In still further examples, the sensors may carryout continuous measurements of the stress characteristic along thesecond stress sensing axis along substantially or the entire length ofevery glass sheet 305.

In further examples, the sensors may be designed to periodically measurestress characteristic information of less than all of the glass sheets305. Periodically measuring stress characteristic information in lessthan all of the glass sheets 305 may be desirable, for example, if themeasurement process would damage or destroy the glass sheet. In suchexamples, a sufficient number of sheets may be periodically examined, asmentioned above, to accommodate changes in stress characteristicinformation while minimizing material waste due to destructive testingof the glass sheets. In one example, at least one glass sheet may bemeasured every 24 hours, such as every 4 hours, such as every hour. Infurther examples, at least one glass sheet out of 60 glass sheets may bemeasured, such as at least one glass sheet out of 240 glass sheets, suchas at least one glass sheet out of 1440 glass sheets. In furtherexamples, other percentages of glass sheets or times between measuringglass sheets may be selected based on the particular application.

In further examples, the method can include the step of averaging thestress characteristic in a longitudinal direction to obtain an averagestress characteristic at each lateral location along the width “W” ofthe glass ribbon 103, wherein the average stress characteristics can beused in subsequent steps 403 and 405 discussed below. For instance, theaverage stress observed by each sensor element 317 may determine theaverage stress characteristic at that particular lateral location over aperiod of time.

Turning back to FIG. 4, the method can then include the steps 403 ofdetermining an adjustment for the temperature adjustment elements 223and then the step 405 of changing the transverse temperature profile ofthe glass ribbon 103 by independently adjusting operation of theplurality of temperature adjustment elements 223 positioned along thewidth “W” of the glass ribbon 103 in at least one of the viscous zone307, the setting zone 309 and the elastic zone 311. As schematicallyillustrated in FIG. 4, the determination can be based on stresscharacteristic information obtained during the step 401 of sensing.

The step 403 of determining an adjustment for the temperature adjustmentelements 223 can be carried out with various techniques. For example, asschematically shown in FIG. 4, a database 407 of power adjustments andcorresponding impact on a stress characteristic of a glass sheet can beprovided. In some examples, the database can be created by actualobserved impacts on a stress characteristic based on a particular powermove. In further examples, the database 407 can be obtained using amodel of an apparatus for producing glass ribbon. In still furtherexamples, a model may be used to create an initial database 407 that isupdated with actual observed impacts on the stress characteristic basedon subsequent power moves.

As such, the desired stress move can be matched as closely as possiblewith the database of achieved stress moves. The corresponding power moveassociated with the closest stress move in the database can then beselected. Alternatively, the power move can be interpolated between thetwo closest power moves. Once the power move is determined, the powermove for each temperature adjustment element 223 can be adjusted by thedetermined power move. As such, it will be appreciated that the power toone or all of the temperature adjustment elements 223 may beindependently adjusted by comparison of the stress characteristicinformation obtained with a database of power adjustments andcorresponding previously observed impact on a stress characteristic of aglass sheet.

In some examples, the database 407 may remain static, and thereby remainunchanged over a period of time or until updated, if ever, at some timein the future. For example, as shown in FIG. 4, after the step 405 ofchanging the transverse temperature profile of the glass ribbon 103 byindependently adjusting operation of the plurality of temperatureadjustment elements 223, the method may return to the step 401 ofsensing as indicated by arrow 409. Next, the method may again carry outthe step 403 of determining the adjustment for the temperatureadjustment elements 223 as indicated by arrow 411.

Alternatively, the method can further comprise the step of adapting thedatabase 407 of the power adjustments and the corresponding impact onthe stress characteristic of the glass sheet based on the stresscharacteristic information obtained after adjusting the operation of thetemperature adjustment elements 223. For example, referring to FIG. 4,after the step 405 of changing the transverse temperature profile of theglass ribbon 103 by independently adjusting operation of the pluralityof temperature adjustment elements 223, the method may return to thestep 401 of sensing as indicated by arrow 409. Next, as indicated byarrow 413, the database 407 can be adapted (e.g., updated) based on thestress characteristic information sensed after adjusting the temperatureadjustment elements in accordance with the determination made duringstep 403. In one example, the database can increase in size with eachupdate. Alternatively, older information in the database can besubstituted with newer information.

The step 403 of determining an adjustment for the temperature adjustmentelements 223 can also be carried out with alternative methods. Forexample, the power adjustments may be calculated using a formula asindicated by box 415 and referenced by equations (1) and (2) above. Infurther examples, the power adjustments may be determined by fuzzy logicas indicated by box 417.

The method can also be designed to prevent the temperature adjustmentelements from operating beyond the specifications of the temperatureadjustment element that may cause failure of the temperature adjustmentelement. If the adjustment of the power provided to the temperatureadjustment element intended to be adjusted would result in an adjustedpower that exceeds a maximum amount of power allowed for the temperatureadjustment element, the power to an adjacent temperature adjustmentelement may be adjusted. The adjacent element can be a single element ortwo elements straddling the intended temperature adjustment element. Forinstance, the excess temperature move can be divided in half and addedto the two adjacent temperature adjustment elements.

As mentioned previously, the method can begin with the step 401 ofsensing. Alternatively, as shown in FIG. 4, the method may include, suchas begin with, step 419 of measuring a parameter associated withmechanically induced stress in the glass ribbon 103. Once the parameteris measured, a decision block 421 is used to prevent thermal stresscompensation if the measured parameter is outside an operating rangeassociated with the parameter. For example, the parameter sensor 335(see FIG. 3) may comprise a motion sensor that determines if the ribbonis swinging or otherwise moving outside of acceptable ranges. If theribbon is swinging with a large enough amplitude, mechanical stress fromthe swinging motion may dominate the stress introduced to the glassribbon. If this is the case, the method loops back to check theparameter again as indicated by arrow 423. Although not shown, loopingback can trigger an audio, visual or other alarm and/or recordingmechanism to help address the source of mechanically induced stress. Ifthe parameters are within acceptable range(s), then the method cancontinue to the step 401 of sensing as indicated by arrow 423.

As such, example methods may optionally include the step 419 ofmeasuring a parameter associated with mechanically induced stress in theglass ribbon 103. In some examples, the method can include the step ofchanging a transverse temperature profile of the glass ribbon only ifthe measured parameter is within an operating range associated with theparameter. If within the acceptable range, the transverse temperatureprofile can be changed by independently adjusting operation of aplurality of the temperature adjustment elements 223 positioned alongthe width “W” of the glass ribbon 103 in at least one of the viscouszone 307, the setting zone 309 and the elastic zone 311. As mentionedpreviously, the temperature adjustment elements 223 can be independentlyadjusted based on stress characteristic information obtained by thesensor elements 317 during the step of sensing the glass ribbon 103 atrespective lateral locations (e.g., L₁, L₂, etc.) along the width “W” ofthe glass ribbon 103.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the present disclosurewithout departing from the spirit and scope of the invention. Thus, itis intended that the present invention cover the modifications andvariations of this disclosure provided they come within the scope of theappended claims and their equivalents.

1.-8. (canceled)
 9. A method of producing a glass ribbon including thesteps of: (I) drawing molten glass from a drawing device in a drawdirection into a viscous zone located along the drawing direction toform a glass ribbon including opposed edges extending in the drawdirection, wherein the opposed edges are spaced apart along a width ofthe glass ribbon that is transverse to the draw direction; (II) drawingthe molten glass from the viscous zone into a setting zone downstreamfrom the viscous zone, wherein the glass ribbon is set from a viscousstate to an elastic state; (III) drawing the glass ribbon into anelastic zone downstream from the setting zone wherein a cross sectionalprofile of the glass ribbon is frozen; (IV) at least periodicallysensing a stress characteristic of the glass ribbon at respectivelateral locations along the width of the glass ribbon; and (V) at leastperiodically changing a transverse temperature profile of the glassribbon by independently adjusting operation of a plurality oftemperature adjustment elements positioned along the width of the glassribbon in at least one of the viscous zone, the setting zone and theelastic zone, wherein the temperature adjustment elements areindependently adjusted based on stress characteristic informationobtained during the step (IV) of sensing the stress characteristic. 10.The apparatus of claim 9, wherein the temperature adjustment elementsare periodically independently adjusted based on stress characteristicinformation periodically obtained during the step (IV) of sensing thestress characteristic.
 11. The method of claim 9, wherein step (V)independently adjusts a power provided to the temperature adjustmentelements by comparison of the stress characteristic information obtainedduring step (IV) with a database of power adjustments and correspondingimpact on a stress characteristic of a glass sheet.
 12. The method ofclaim 11, further comprising the step of adapting the database of thepower adjustments and the corresponding impact on the stresscharacteristic of the glass sheet based on the stress characteristicinformation obtained during step (IV) after adjusting the operation ofthe temperature adjustment elements.
 13. The method of claim 11, whereinthe database is obtained using a model of an apparatus for producingglass ribbon.
 14. The method of claim 9, wherein step (IV) furthercomprises the step of averaging the stress characteristic in alongitudinal direction to obtain an average stress characteristic ateach lateral location along the width of the glass ribbon, wherein theaverage stress characteristics are used as the stress characteristicinformation during step (V).
 15. The method of claim 9, furthercomprising the step of measuring a parameter associated withmechanically induced stress in the glass ribbon, and preventing thermalstress compensation if the measured parameter is outside an operatingrange associated with the parameter.
 16. A method of producing a glassribbon including the steps of: (I) drawing molten glass from a drawingdevice in a draw direction into a viscous zone located along the drawingdirection to form a glass ribbon including opposed edges extending inthe draw direction, wherein the opposed edges are spaced apart along awidth of the glass ribbon that is transverse to the draw direction; (II)drawing the molten glass from the viscous zone into a setting zonedownstream from the viscous zone, wherein the glass ribbon is set from aviscous state to an elastic state; (III) drawing the glass ribbon intoan elastic zone downstream from the setting zone wherein a crosssectional profile of the glass ribbon is frozen; and (IV) measuring aparameter associated with mechanically induced stress in the glassribbon, and only if the measured parameter is within an operating rangeassociated with the parameter, then changing a transverse temperatureprofile of the glass ribbon by independently adjusting operation of aplurality of temperature adjustment elements positioned along the widthof the glass ribbon in at least one of the viscous zone, the settingzone and the elastic zone, wherein the temperature adjustment elementsare independently adjusted based on stress characteristic informationobtained by sensing the glass ribbon at respective lateral locationsalong the width of the glass ribbon.
 17. The method of claim 16, whereinthe step of changing the transverse temperature profile during step (IV)independently adjusts a power provided to each of the temperatureadjustment elements based on a comparison of the sensed stresscharacteristic information with a database of power adjustments andcorresponding impacts on a stress characteristic of a glass sheet. 18.The method of claim 17, wherein step (IV) includes adjusting a powerprovided to a temperature adjustment element adjacent to the temperatureadjustment element that is intended to be adjusted, if the adjustment ofthe power provided to the temperature adjustment element intended to beadjusted in step (IV) would result in an adjusted power that exceeds amaximum amount of power associated with that temperature adjustmentelement.
 19. The method of claim 16, wherein the stress characteristicinformation is obtained by averaging the sensed stress characteristicinformation in a longitudinal direction to obtain an average stresscharacteristic at each lateral location along the width of the glassribbon.
 20. The method of claim 16, wherein the temperature adjustmentelements are periodically independently adjusted based on stresscharacteristic information periodically obtained by sensing the glassribbon at respective lateral locations along the width of the glassribbon.